Dna sequence encoding proteins conferring phytophthora infestans resistance on plants

ABSTRACT

Genomic sequences encoding  Phytophthora infestans  resistance proteins are provided herein. Specifically, sequences from potato required for  P. infestans  resistance have been cloned and sequence provided, together with the encoded amino acid sequence. DNA encoding the amino acid sequence or amino acid sequences showing a significant degree of homology thereto may be introduced into plant cells and the encoded polypeptide expressed, conferring  P. infestans  resistance on plants comprising such cells and descendants thereof.

FIELD OF THE INVENTION

[0001] This invention relates to methods and materials for improved plant disease resistance. In particular the present invention relates to nucleic acid sequences required for resistance of potato to Phytophthora infestans, recombinant polynucleotide molecules containing the sequences, and uses thereof to transform plants, especially plants of the family Solanaceae to make them more resistant to Phytophthora species.

BACKGROUND OF THE INVENTION

[0002] The oomycete pathogen Phytophthora infestans, is worldwide the main disease of the potato crop causing late blight that results in major losses of crop yield and quality. P. infestans infects plants of commercial importance like potato and tomato, that therefore require regular chemical control. Monogenic R genes have been introduced from the hexaploid Mexican wild species Solanum demissum into the cultivated tetraploid potato cultivars (Wastie, 1991). These race specific R genes did not provide durable field resistance because of the rapid evolution of new virulent races of the fungus that circumvent these R gene mediated resistances. Characteristic for R gene mediated resistance reactions is the hypersensitive response (HR) leading to local cell death causing necrotic spots at the site of attempted infection. Genetic analysis showed that activation of HR is highly specific and induced upon recognition by a specific R gene product and a corresponding avirulence gene product in the pathogen (Hammond-Kosack and Jones, 1997).

[0003] The R gene mediated resistance from wild Solanum species can show partial resistance or an intermediate HR response when crossed to different S. tuberosum backgrounds (Graham, 1963; Toxopeus, 1958). The HR lesions can vary in size depending on the backcross parent used, indicating that other genes influence the R gene resistance reaction. Minor S. tuberosum or S. demissum genes have been characterized to influence or even suppress R gene expression (El-Kharbotly et al., 1996b). QTL mapping in S. tuberosum populations segregating for partial P. infestans resistance, identified 19 QTLs on 13 chromosomal regions (Leonards-Schippers et al., 1994), with one QTL on chromosome 5 near the P. infestans resistance locus R1 also linked to QTLs for maturity and vigor (Collins et al., 1999). These QTLs on chromosome 5 very likely represent minor genes that play a role in both R gene mediated HR resistance responses and developmental processes which indirectly influence the resistance response. Additionally, this chromosome region also contains several other resistance loci with specificity to different pathogens like the PVX virus (Ritter et al., 1991) and potato cyst nematodes (Kreike et al., 1994; Rouppe van der Voort et al., 1998).

[0004] The cloning of genes that mediate gene-for-gene type resistance to bacterial, fungal, oomycete, viral, and nematode pathogens has so far identified 5 classes of genes based on common characteristics including nucleotide binding sites, leucine-rich repeats, transmembrane domains and serine/threonine protein kinases (Hammond-Kosack and Jones, 1997). Genetic mapping and sequence analysis showed frequent clustering of R genes with different resistance specificities at complex loci (Jia et al., 1997; Parniske et al., 1997). Despite these insights into R gene structure their function can not be predicted from sequence alone and functional tests are required to determine their role in resistance (Parker et al., 1996).

[0005] A few R gene signal transduction components have been identified by mutation (reviewed in Innes, 1998). These analyses have helped identify genes that are required for the barley powdery mildew mediated Mla-12 resistance (rar-1 and rar-2; Jorgensen, 1996), the tomato Pseudomonas syringae pv tomato resistance gene Pto (Prf; Salmeron et al., 1996) and Pti; (Zhou et al., 1995) and for the tomato Cf-9 (rcr-1 and rcr-2; Hammond-Kosack and Jones, 1994) and Cf-2 mediated Cladosporium fulvum resistance reactions (rcr-3; Jones et al., 1999). Extensive mutant screens in Arabidopsis identified a number of genes involved in plant pathogen interactions, ndr1 (Century et al., 1995), eds1 (Parker et al., 1996), pad1, pad2, pad3 and pad4 (Glazebrook et al., 1996) and pbs1, pbs2 and pbs3 (Warren et al., 1999) Most of these mutations affect the function of a subset of R genes (Aarts et al., 1998) or only combinations of double mutations significantly decease R gene resistance (Glazebrook et al., 1997; Warren et al., 1999; McDowell et al., 2000). This indicates the occurrence of different signaling pathways for resistance reactions that are also partially redundant.

[0006] Transposon tagging is an established tool in plants for the identification of genes that display a mutant phenotype when their function is disrupted. Transposons have been introduced from maize and successfully used for tagging in many heterologous plants like Arabidopsis (Aarts et al., 1993), petunia (Chuck et al., 1993), tobacco (Whitham et al., 1994), tomato (Jones et al., 1994) and flax (Lawrence et al., 1995). In these self-fertilizing plant species random tagging strategies (Arabidopsis, petunia) by screening large selfed populations for mutants or targeted tagging of specific genes (tobacco, tomato, flax) were applied. By self- or test-crossing, large populations were produced for the direct screening of possible transposon tagged mutants. By using selectable markers like kanamycin (Baker et al., 1987) or hygromycin (Rommens et al., 1992), selection of excision events at the cellular level has been feasible and in combination with effective in vitro selection and somatic propagation procedures can facilitate the production of large numbers of transposon insertion mutants.

SUMMARY OF THE INVENTION

[0007] The present invention provides an isolated DNA sequence which encodes a protein having the amino acid sequence given in SEQ ID NO:2 or a functionally homologous protein having an amino acid sequence showing an identity of at least 80% to SEQ ID NO:2, which protein confers Phytophthora infestans resistance on plants.

[0008] Preferably, the DNA sequence encodes a protein having an amino acid sequence showing an identity of at least 85%, or even 90%, to SEQ ID NO:2.

[0009] More preferably, the DNA sequence encodes the amino acid sequence given in SEQ ID NO:2, in which case the DNA sequence comprises the nucleotide sequence given in SEQ ID NO:1.

[0010] More general, the invention provides the DNA sequence selected from the group consisting of:

[0011] a) the DNA sequence given in SEQ ID NO:1 and its complementary strand, and

[0012] b) DNA sequences hybridizing to the sequences in (a) under stringent hybridization conditions.

[0013] In particular the DNA sequence comprises the nucleotide sequence of nucleotides 20 to 1053 of SEQ ED NO:1, which is the coding sequence for the protein having the amino acid sequence given in SEQ ID NO:2. Said nucleotide sequence contains an intron, nucleotides 584 to 726. Accordingly, the actual DNA sequence encoding the protein of SEQ ID NO:2 comprises nucleotides 20 to 583 and 727 to 1053 of SEQ ID NO:1.

[0014] In a further aspect the invention provides a protein having the amino acid sequence given in SEQ ID NO:2 or a functionally homologous protein having an amino acid sequence showing an identity of at least 80% to SEQ ID NO:2, which protein confers Phytophthora infestans resistance on plants.

[0015] In another aspect the invention provides a recombinant vector comprising a DNA sequence as defined above under control of an appropriate promoter and regulatory elements for expression in a host cell.

[0016] In still another aspect the invention discloses the use of the present DNA sequence or recombinant vector for the production of a transgenic plant.

[0017] Further invention provides a host cell, preferably a plant cell, comprising the present DNA sequence or recombinant vector.

[0018] Also provided is a plant or any part thereof comprising such plant cell, and seed, selfed or hybrid progeny or descendant of such a plant, or any part thereof.

[0019] The invention also provides a method of conferring Phytophthora infestans resistance on a plant, comprising the steps of

[0020] i) introducing a DNA sequence as defined above or a recombinant vector as defined above into a cell of the plant or an ancestor thereof,

[0021] ii) regenerating plants from the obtained transgenic cells, and

[0022] iii) selecting plants exhibiting P. infestans resistance.

[0023] A further aspect of the invention is the provision of oligonucleotide probes that comprise a sequence of nucleotides of SEQ ID 1, or a mutant, derivative or allele thereof, capable of detecting the pathogen resistance gene or functional equivalents thereof in plants of the family Solanaceae and the use of the probes to isolate DNA sequences encoding a pathogen resistance gene or a functional equivalent thereof.

[0024] Using the sequence SEQ ID 1 facilitates the isolation of homologous genes from related and unrelated hosts to obtain genes, which protect host plants against related and unrelated pathogens.

[0025] A further aspect of the invention is the identification of proteins that interact with constructs comprising sufficient homology to SEQ ID 2, the genes thereof can be used to provide plant cells that are resistant to pathogens. One way is by identification of interacting proteins by the yeast two-hybrid system that are then involved in the signal transduction of the resistance response.

[0026] A further aspect of the invention is the construction of hybrid proteins comprising SEQ ID 2 or DNA isolates of sufficient homology, with other proteins that can be used as effector molecules. One way is by making hybrids with different leucine rich repeat fragments from various plants or synthetically produced in vitro, that can interact with different pathogen or inducer effector molecules. These effectors can also be chemically produced and by application to a plant containing the hybrid construct can induce the signal transduction pathway for resistance.

BRIEF DESCRIPTION OF THE DRAWINGS

[0027]FIG. 1: Schematic drawing of pHPT:Ds-Kan showing positions of primer 1 (pI, GCG CGT TCA AAA GTC GCC TA), primer 2 (p2, GTC AAG CAC TTC CGG AAT CG) and PstI restriction sites. Abbreviations: LB=left border, RB=right border, pNOS=nopaline synthase promoter, NPT II=neomycin phosphotransferase gene, HPT II=hygromycin phosphotransferase gene.

[0028]FIG. 2: PstI restriction of genomic DNA hybridized to NOS promoter probe to select for presence of full donor site (FDS=4.0 kb), empty donor site (EDS=2.3 kb), Ac T-DNA construct (3.5 kb) and Ds re-insertion sites in the R1Ds/r-; Ac/-selected seedlings EE96-4311-37 (lane 1), EE96-4312-43 (lane 5) EE96-4312-49 (lane 9) and HygR protoplast regenerants from EE96-4311-37 (lane 2,3 and 4), EE96-4312-43 (lane 6, 7 and 8), EE96-4312-49 (lane 10, 11, 12 and 13), EE96-4311-15 (lane 13, 15), EE96-4312-05 (lane 14), EE96-4312-76 (lane 16) and EE96-4312-06 (lane 17).

[0029]FIG. 3: Reaction phenotypes observed on different genotypes after inoculation of detached leaves with P. infestans race 0. a) TM17-2, susceptible parent; b) detail of sporulation on TM17-2; c) HRPR 836; d) HRPR 1587 showing both the R1 type HR response and necrotic regions with sporulation; e) detail of HR spot on HRPR 1587; f) detail of sporulation on the necrotic region of HRPR 1587; g) necrotic regions on R1Ds/r-, Ac/-seedling EE96-4312-03, minor sporulation was detected in such regions; h) clear colonization on variant 1000; i) detail of sporulation on variant 1000.

[0030]FIG. 4: HindIII digested genomic DNA hybridized to the 5′ Ac probe (A) or the internal Ac probe (B). Lane 1 shows the 1.6-kb marker hybridization. The R1 resistant crossing parent J91-6167-2 (lane 2a and b) and the susceptible crossing parent 87-10242 (lane 3a and b) contain both no Ac or Ds elements. The primary tansformant Ds416 contained two Ds T-DNA loci (lane 4a), Ds53-34 inherited both Ds T-DNA loci (lane 5a) as did EE96-4312-28 (lane 7a). EE96-4312-28 inherited from TM17-2 (lane 6a) the Ac element. In mutant 487 (lane 8a) and mutant 1000 (lane 9b), both regenerated from EE96-4312-28, the Ds elements transposed to new positions and Ac seems to be missing. In TM17-2 (lane 6b) a complete Ac (1.6 kb internal HindIII fragment) and a dAc (2.9 kb) are present. Mutant 487 lane 8b) inherited dAc as a different restriction fragment due to the insertion of Ac in dAc. In mutant 1000 (lane 9b) Ac got lost and only dAc is present.

[0031]FIG. 5: a) Schematic representation of the isolated Ds flanking sequences from mutant 1000 (rpr1 and rpr2) and their alignment to XA21 aa 708-1011. The large triangles represent the Ds positions, the intron region is a dashed line and the small black triangles represent primer positions of EE1 (5′-ACA TTG GGC ACT CTT GGA TAC A), EE2 (5′-TCT TGA TTC TGG CAT TTT CTT TG), EE3 (5′-CCT GAC ACA AAC CGA GAC ATT, EE6 (5′-AAC AAT GCC TTT CTT CTC), EE8 (5′-GCA CAT TAT CAA GTG GAA CTA CG) and EE10 (5′-CTG AGC CGT ACT CTT AAA AGA ACG). b) Amino acid alignment of Pto, Ptil, StPK-B, StPK-A and Xa21. The eleven conserved domains of a protein kinases are numbered and the conserved amino acids are marked (*). Bold domains are specific for serine/threonine recognition. The N-glycosylation site is underlined.

[0032] FIGS. 6(A and B): Sequence of the StPK-B DNA (SEQ ID NO: 1) and StPK-B protein (SEQ ID NO: 2). StPK-B DNA sequence is the contiguous sequence of a DNA fragment obtained by isolating the Ds tagged gene. The sequence is part of the StPK-B gene encoding the protein kinase domain and lacks the N-terminal portion of the gene including the translation start. SEQ ID 2 is the amino acid translation of SEQ ID 1 after removing the predicted intron conserved with other gene family members.

[0033]FIG. 7: DNA sequences of StPK homologs obtained by using primers EE1 and EE2. SEQ ID 3 is the sequence of DNA fragments of StPK-A that is tagged by the transposon Ds. SEQ ID 4-12 are DNA fragments obtained by PCR between primers EE1 and EE2; Seq ID 4-12 represent fragments of homologous sequences StPK-C to StPK-K, in the genome.

[0034]FIG. 8: Diagram of StPK overexpression constructs used for plant transformation. The StPK-B gene with a synthetic translation initiation start, under control of the CaMV 35S promoter and Nos-terminator is cloned in a binary vector for transformation of plants using Agrobacterium tumefaciens strains in construct I. Construct II contains the N-terminal part of the StPK genes or other N-terminal fusions to protein domains that act as recognition domains with other effector molecules.

DETAILED DESCRIPTION OF THE INVENTION AND EXPERIMENTS Development of Transposon Mutagenized Potato Plants

[0035] Diploid potato plants heterozygous for the P. infestans R1 resistance gene were transformed with an Agrobacterium strain containing a Ds-transposon T-DNA construct shown in FIG. 1 (Pereira et al., 1992; El-Kharbotly et al., 1995). Transformant Ds416 contained a Ds T-DNA insertion on chromosome 5 (El-Kharbotly et al., 1996a), linked in repulsion phase to the previously mapped P. infestans R1 resistance gene (Leonards-Schippers et al., 1992). This Ds416 clone was crossed to the susceptible diploid genotypes J89-5040-2 producing offspring that enabled the selection of recombinant plants (Ds53-22 and -34) having the R1 gene and the Ds T-DNA in coupling phase (18 cM) (El-Kharbotly et al., 1996a). To activate the Ds transposon these plants were crossed with TM17-2, a diploid potato clone susceptible to P. infestans and transformed with the Ac transposon-containing T-DNA construct pMK1GBSSAc (Pereira et al., 1991). TM17-2 contained one functional Ac displaying active transposition. From the progeny of these crosses, population EE96-4311 (Ds53-22 X TM17-2; 18 seedlings) and EE96-4312 (Ds53-34 X TM17-2; 96 seedlings), 47 (8 and 39) kanamycin resistant R1 seedlings (KanR R1) were selected.

[0036] Plant genomic DNA was isolated from greenhouse grown leaves (Pereira and Aarts, 1998) and use for molecular analysis. Empty donor sites (EDS-PCR) indicating excision were detected in 22 of the 47 KanR R1 seedlings as a 450-bp PCR product using specific primers FIG. 1) and confirmed by Southern blot analysis. After selection of the 22 R1 resistant seedlings showing active Ds excision (R1Ds/r-; Ac/-), the expression of hygromycin resistance (HygR) was tested by rooting on MS30 supplemented with 10-100-mg/l hygromycin. One genotype EE9643-4311-12 showed resistance by rooting on 40 mg/l hygromycin and displayed a clear EDS fragment, suggesting that screening for rooting of shoots on 40 mg/l could be used as a stringent criteria for Ds excision.

[0037] As most genotypes contained excision events that occurred late in shoot development these HygR cells could be selected by protoplast isolation and screening for hygromycin resistance to select independent excision events. Protoplasts were isolated from 4-week-old in vitro grown shoots (Uijtewaal et al., 1987), re-suspended in culture medium TM2G (Wolters et al., 1991) to a final concentration of 500,000 pp/ml and diluted weekly with fresh medium. The regenerating calli were progressively transferred to callus growth medium, shoot induction medium and finally maintained on shoot elongation medium until regenerated plants could be harvested (Mattheij et al., 1992). In separate experiments to select specifically for protoplast regenerants with excision events, 10 mg/l hygromycin was added to the callus growth medium 14 days after protoplast isolation, then increased to 20 mg/l on day 21 and maintained at this level.

[0038] Table 1 gives an overview of protoplast regeneration data. From parental clone Ds53-34, control EE96-4312-21 and selected R1Ds/r-; Ac/-seedlings about 50 regenerating shoots were tested for their rooting ability on MS30 with 40 mg/l hygromycin. As expected, the parent Ds53-34 and control EE96-4312-21 produced no HygR protoplast regenerants whereas EE96-4311-12 gave 45% HygR protoplast regenerants confirming early excision. The other 14 good performing R1Ds/r-; Ac/-plants showed regeneration of 4 to 33%′ of HygR shoots indicating excision of Ds from its original T-DNA location. The use of hygromycin selection during callus culture and regeneration of shoots increased to recovery of HygR regenerants 3.8 times. A total of 1973 HygR regenerants were obtained from different selection experiments and transferred to the greenhouse. TABLE 1 Selection of excision events after protoplast regeneration with and without hygromycin selection. Number of calli, shoots and selected hygromycin resistant (HygR) regenerants for parents Ds53-22 and Ds53-34; control EE96-4312-21 (R1Ds/r-; —/—) and 22-selected R1Ds/r-; Ac/— genotypes from the seedling populations EE96-4311 and EE96-4312. No selection During Hygromycin selection protoplast regeneration During protoplast regeneration Genotype Calli Shoots HygR Calli Shoots HygR Ds53-22  10  0  47 0 Ds53-34 100 45  0  134 1 0 EE96-4312-21 100 21 0  900 10 0 EE96-4311-08   0^(a)   0^(a) EE96-4311-12 100 49 22 1000 198 98 EE96-4311-15 300 82 11  800 160 101 EE96-4312-03 100 23 3 1000 166 83 EE96-4312-05 100 29 8 1000 198 121 EE96-4312-06 100  6^(a) 2 1000 205 139 EE96-4312-14 100 70 15 1000 208 118 EE96-4312-23 100 51 2 1000 211 91 EE96-4312-27  10  0  10 0 EE96-4312-28 100 47 7 1000 143 82 EE96-4312-30 100  0  419 0 EE96-4312-31 100 30 2  570 21 4 EE96-4312-37 100 52 2 1000 248 92 EE96-4312-40  33  2 0  67 0 EE96-4312-43 100 45 8  650 207 101 EE96-4312-46  14  9 0  103 0 EE96-4312-49 100 48 3 1000 206 109 EE96-4312-52  3 3 0   1 1 1 EE96-4312-60 100 52 7 1000 203 93 EE96-4312-63 100 50 7 1000 203 130 EE96-4312-76  0  0  24 0 EE96-4312-89 100 49 4  274 41 19 Total 691 103 2619 1382

[0039] To analyze Ds excision in the HygR protoplast regenerants Southern blot hybridization was performed on a subset of selected R1Ds/r-; Ac/-seedlings and some of their HygR protoplast regenerants (FIG. 2). Plant DNA was restricted with Pst1 and the blots hybridized to probes derived from the NOS promoter fragment that revealed the Ac T-DNA and the Ds transposon. The R1Ds/r-; Ac/-seedlings used for protoplast isolation all displayed two PstI fragments, respectively 4.0- and 3.5-kb, corresponding to respectively the Ds T-DNA and the Ac T-DNA constructs. Faintly visible fragments of 2.3-kb were also detected that correspond to a low amount of EDS fragments present in these seedlings. All HygR protoplast regenerants showed a strong hybridizing EDS fragment indicating early or repeated excision of Ds corresponding to the high level of hygromycin resistance for which these plants were selected. The original Ds parent had two copies of Ds at one locus. Full donor site fragments were detected in most of the HygR protoplast regenerants which indicates that one of the two Ds's was not excised. Three plants shown in FIG. 2, showed a complete EDS indicating that excision occurred in the initial protoplast. Most HygR regenerants showed clear Ds re-insertion fragments varying from 1 to 8 new positions per individual HygR regenerant. Regenerants from a single seedling showed different re-insertion patterns, indicating that they originated from independent transposition events and confirmed that most selected HygR regenerants originate from independent transposition events.

[0040] The somatic selection of Ds transpositions from individual cells facilitated the production of a large population of shoots with independent Ds excision events. The HygR protoplast regenerants potentially represent about 2000 independent Ds insertions. This number of Ds insertion mutations should be enough for the isolation of tagged mutants involved in R1 resistance. The somatic selection of Ds transposition and the rapid production of independent plants containing these transpositions, facilitates the production of large tagging populations needed for the transposon mutagenesis of selected genes. This is particularly suitable for the mutagenesis of genes in heterozygous crops like potato.

Screen for R1 Type HR Resistance Variants in the Ds Tagged Population

[0041] The transposon mutagenized population was suitable for the isolation of mutations in defense related genes causing an altered reaction to P. infestans. By using a suitable screen quantitative changes towards susceptibility were possible to be identified. Race specific resistance Cf genes in tomato have shown a semidominant phenotype if screened in a quantitative manner (Hammond-Kosack and Jones, 1994). Chromosome 5 in potato is known to contain many resistance components (Leonards-Schippers et al., 1994) that are probably in a heterozygous state as seen from segregation of minor factors. These loci could probably be efficiently mutagenized due to active linked transposition of Ds near R1.

[0042] To prepare the inoculum for screening (El-Kharbotly et al., 1994), P. infestans race 0 (89148-09) was grown on rye agar medium (with 20 m/l sucrose). The sporangiospores were washed with 10-15 ml cold tap water (4° C.) and the resulting suspension used to inoculate 10 Bintje tuber slices (1 cm thickness). The newly formed sporangiospores were washed and again used to inoculate 20-50 tuber slices of Bintje in order to obtain 1-2 l of sporangiospore solution. This solution was diluted to contain at least 2000 spores/ml to use for plant inoculation.

[0043] The 1973 hygromycin resistant protoplast regenerant (HRPR's) plants to be tested were periodically brought in batches to the greenhouse. After 6-10 weeks growth two leaves of each HRPR plant were harvested, placed in columns of water absorbent substrate, and put in containers (46×31×8 cm) closed with transparent covers. In every container two leaves of 10 HRPR plants and a leaf of the susceptible control (Bintje or TM17-2) were tested. In each experiment 15-30 containers were used so that 150-300 plants could be tested in parallel, with Ds53-22, Ds53-34 and TM17-2 always tested as additional controls. Each leaf in the experiments was sprayed with about 5-10 ml of the sporangiospore solution containing 10,000-50,000 sporangiospores. After 5 days in high humidity at 16° C., all leaves were evaluated for the development of P. infestans infection symptoms and at day 6 a second evaluation for disease symptoms was performed. When development of symptoms occurred the leaves were kept for an additional 2 days for a mnicroscopic examination of the disease development.

[0044] The susceptible parent and control cultivar Bintje always showed distinctive colonization and abundant sporulation on day 5-6 (FIGS. 3a and 3 b). In contrast the resistant parents Ds53-22, Ds53-34 and most of the analyzed HRPR's always displayed characteristic R1 type HR spots upon infection. The phenotype of HRPR 936 was distinctly susceptible with colonization and sporulation over large leaf areas (FIG. 3c). Other HRPR's sometimes showed larger necrotic regions indicating colonization of the leaves (FIG. 3d). When this colonization resulted in sporulation (FIG. 3f) the HRPR was scored as a potentially susceptible R1 variant, although necrotic spots were additionally visible on the green parts (FIG. 3e) indicating at least a partial HR activation. In this first round of screening 33 putative susceptible variants, derived from 10 R1Ds/r-; Ac/-seedlings were selected (Table 2). Re-inoculation tests of newly grown leaves of the selected variants confirmed the susceptible reactions for 9 variants. TABLE 2 Primary screen for mutants with an altered R1 type HR resistance response. # HRPR's total # tested with R1Ds/r-; Ac/— selected P. infestans # HRPR's Variant Ploidy Seedling HRPR's race 0 Variant plant # level EE96-4311-12 126 72 1  702 4x EE96-4311-15 112 81 2  35 2x  994 2x EE96-4312-03 86 63 2  1515^(a) 2x 1921 nd EE96-4312-05 129 84 2  836^(a) 4x  842 4x EE96-4312-06 243 188 EE96-4312-14 195 168 2  925 4x 1587 2x EE96-4312-23 93 82 EE96-4312-27 5 0 EE96-4312-28 89 71 7  487^(a) 2x  998 2x  999 4x 1000 2x 1001 4x 1005 4x 1357 2x EE96-4312-31 7 4 EE96-4312-37 134 120 4  151^(a) 4x  510^(a) 4x  524 2x  551 4x EE96-4312-43 109 91 6  570^(a) 4x  688^(a) 4x 1528 4x  561 x-4x  562 x-4x  574 4x EE96-4312-49 152 111 6  600 4x  601 4x  633^(a) 2x 1050 2x  1055^(a) 4x 1073 4x EE96-4312-52 1 1 EE96-4312-60 134 112 1  667 4x EE96-4312-63 168 155 EE96-4312-76 83 65 EE96-4312-89 107 96 Total 1973 1564 33

[0045] Selected genotypes were transferred from the greenhouse to in vitro for propagation to obtain 10 or 35 cuttings of each variant and these were transferred again to the greenhouse for a replicated re-testing of the P. infestans R1 resistance. From the first set of 33 R1 variants, ploidy level analysis enabled the identification of plants with chromosomal anomalies that were potentially somaclonal variants. All the diploid variants together with those with a reproducible susceptible phenotype and the corresponding 9 parental seedlings were used for a secondary quantitative phenotypic analysis. After P. infestans inoculation on two leaves of each plant, the developing symptoms we carefully evaluated and followed microscopically when necessary to detect sporulation (Table 3). TABLE 3 Qualitative and quantitative analysis of the resistance reaction and disease development on selected variants compared to parental controls. % leaves with 20-100% % leaves necrosis, with colonization % <20% sporulation & leaves necrosis (max % leaf Dead # with and spor- area (Rot- plants HR ulation covered) ten) Parents Ds53-34 10 100 0 0 0 TM17-2 10 0 0 100 (100) 0 R1Ds/r-; Ac/— Seedlings EE96-4312-76 10 100 0 0 0 EE96-4312-43 9 94 6 0 0 EE96-4312-37 19 87 13 0 0 EE96-4312-28 20 75 23 2 (35) 0 EE96-4312-49 10 75 20 5 (25) 0 EE96-4312-05 20 75 15 5 (40) 5 EE96-4312-03 21 71 19 10 (60) 0 EE96-4311-15 20 60 35 5 (50) 0 EE96-4312-14 19 47 18 32 (100) 3 Variants EE96-4312-43 570 9 100 0 0 0 688 7 100 0 0 0 EE96-4312-37 510 10 95 5 0 0 524 10 90 5 0 5 EE96-4312-28 487 35 41 43 16 (100) 0 998 34 60 38 2 (35) 0 1000 35 16 34 50 (100) 0 1357 34 63 24 9 (70) 4 EE96-4312-49 601 10 60 30 10 (60) 0 633 10 70 25 5 (60) 0 1050 9 78 17 5 (45) 0 1055 10 80 10 5 (50) 5 EE96-4312-05 836 34 7 12 68 (100) 13 EE96-4312-03 1515 31 76 16 8 (50) 0 EE96-4311-15 35 14 82 0 7 (50) 11 994 8 44 0 56 (100) 0 EE96-4312-14 1587 1 50 0 50 (60) 0

[0046] The R1 resistant parental plant Ds53-34 always showed the complete R1 type HR response, with small necrotic spots on inoculated leaves. The R1 resistant progeny of Ds53-22 and Ds53-34 (EE96-4311-15 and EE96-4312-03, 05, 14, 28, 37, 43, 49 and 76) displayed an intermediate resistance phenotype (Table 3). With the exception of seedling EE96-4312-76, all other seedlings showed on several leaves (6-35%) necrotic spots that developed into necrotic regions covering 5 to 20% of the leaf area (FIG. 3g). Microscopic examination revealed very little sporulation in these regions indicating minor escape of P. infestans from the normal R1 type HR response. In a few leaves the necrotic region covered almost 100% of the leaf area and colonization with sporulation was observed indicating susceptibility of the leaf and escape from the R1 type HR resistance response. Seedling EE96-4312-14 showed in this analysis only in 47% of the leaves a clear R1 type HR response. However, from the 168 HRPR's derived from this seedling and tested in the first screening for R1 resistances only 2 were selected as putative variants (Table 2). This indicates that the intermediate phenotype for this and other parental seedlings did not result in an overestimation of putative variants in the first screening.

[0047] The re-evaluation of the resistance response reaction for the variants 487, 1000, 836 and 994 showed a clear deviation in phenotype when compared to the parental seedlings. Variant 1000 showed colonization and sporulation on 50% of the leaves and this clearly resembled the TM17-2 P. infestans susceptible parental phenotype (FIGS. 3h and 3 i). Only 16% of the variant 1000 leaves showed the normal R1 type HR resistance response. In variant 487 the R1 type HR resistance response was clearly detected in only 41% of the inoculated leaves. On 16% of the leaves necrotic regions covered over 20% of the leaf area and colonization and sporulation was detected indicating a weak susceptible R1 vaiant.

[0048] The susceptible phenotype of variant 836 in the first screening of the HRPR population (FIG. 3c) was repeatable in this analyses but quick senescence of the leaves, resulting in softening and rotting, suggested other causes for the observed susceptible phenotype. Variant 994 showed a striking phenotype as in every plant the youngest leaf showed colonization with sporulation, combined with leaf softening and rotting. The second oldest leaf analyzed always showed a normal R1 type HR resistance phenotype. The variants 836 and 994 therefore displayed a more susceptible reaction due to interaction with early senescence and were therefore not considered as variants in the expression of R1 type resistance. Re-evaluation of the resistance phenotype of the variants 570, 688, 510, 524, 633, 1050, 1055, 1515 and 35 did not reveal any quantitative difference when compared to the parental seedlings and were not regarded as mutants in the R1 resistance reaction.

Molecular Analysis of the Tagged Mutants

[0049] To examine the causal relationship between the Ds insertion sites and the observed phenotype mutant 1000 was characterized by Southern blot hybridization. Genomic DNA from appropriate genotypes was restricted with HindIII and the blots hybridized to a 5′ Ac probe to determine the presence and positions of the Ac and Ds elements in the different genotypes. Since Ds is derived from Ac, the 5′ Ac probe also identified the Ds element (Pereira et al., 1992). Additional hybridization of the same blots with an Ac probe revealed the presence and position of Ac. In the different genotypes the Ds and Ac insertions were identified by specific HindIII fragments (FIGS. 4a and 4 b). New positions of the Ds elements confirmed that both mutants (from same seedling parent) were derived from different DS transposition events in EE96-4312-28 during protoplast regeneration (FIG. 4a). These hybridizations also revealed that mutant 1000 had lost the Ac element and was therefore a stable mutant.

[0050] To analyze the sites of Ds insertion, flanking DNA of Ds insertions was isolated by inverse PCR (IPCR; Triglia et al, 1998). Plant genomic DNA, was restricted with HaeIII, self-ligated and restricted with BamHI and BglII. BglII restriction prevents the amplification of the Ds transposon flanking sequences in the original T-DNA construct. To obtain additional and longer 5′ flanking sequences a second restriction combination was used, in which genomic DNA was restricted with MscI followed by HindIII and after ligation linearized by ClaI. Primer 5′-CGG GAT GAT CCC GIT TCG TT (Ac position 197-216) and primer 5′-GAT AAC GGT CGG TAC GGG AT (Ac position 44-35) were used to amplify the 5′ Ds/Ac flanking sequences. After a hot start (10 min 94° C.), 35 PCR cycles (1 min 94° C., 1 min 60° C., 2 min 72° C.) resulted in the amplification of Ac and Ds 5′ flanking sequences.

[0051] Thermal asymmetric interlaced (TAIL) PCR (Liu and Whittier, 1995) was used to obtain additional Ds transposon flanking sequences. Sets of nested primers designed on the 5′- and the 3′ site of the Ac transposon (Tsugeki et al., 1996; Ds5-1, 5-2, 5-3, 5-4 and Ds3-1, 3-2 3-3, 3-4) were combined with 4 different degenerated primers (AD1 to 4; Liu and Whittier, 1995) or two other degenerate primers (Tsugeki et al., 1996; renamed AD5 and 6). The three step PCR reactions were performed as described (Tsugeki et al., 1996). Primers AD3, AD5 and AD6 with Ac/Ds 5′ primers and primers AD5 and AD6 with Ac/Ds 3′ primers produced specific PCR fragments.

[0052] The IPCR and TAIL-PCR products were separated on a 1% TBE agarose gel to determine the number and size of fragments. After phenol:chloroform extraction and isopropanol precipitation, the PCR products were cloned in pGEM T easy vector (Promega Corporation). For each sample three clones were sequenced using an automated ABI 373 DNA sequencer. The obtained Ds flanking sequences were compared to known sequences by BlastN and BlastX homology searches (Altschul et al., 1997) in the public databases.

[0053] In mutant 1000 two different Ds insertions were identified by BlastX searches, each with homology to a leucine rich repeat containing protein kinase from Oryza longistaminata (Tarchini et al., 2000) and a receptor protein kinase-like protein from Arabidopsis thaliana (BAC clone F13112). These sequences were both identified due to their homology to the serine/threonine kinase domain of the Xanthomonas resistance gene Xa21 isolated from O. longistaminata (Song et al., 1995). Additional Ds flanking sequences were isolated using TAIL-PCR (540 bp; FIG. 5a). Combining the 5′ 288 bp and the 3′ 540 bp flanking sequence for this Ds insertion revealed the expected 8-bp target site duplication. The sequence flanking this Ds insertion showed 50% protein identity tio XA21. For the second Ds insertions the IPCR and TAIL-PCR only extended the 5′ flanking sequence from 496 to 1309 bp (FIG. 5a). This sequence covered a complete serine/threonine protein kinase ORF (nucleotides 20 to 583 and 727 to 1053) with 44% identity to the serine/threonine protein kinase domain of XA21 including the conserved intron position, nucleotides 584 to 726 (FIG. 5a). All eleven protein kinase specific domains with conserved features were present (FIG. 5b) as well as all the 14 conserved amino acids (Hanks et al., 1988). Domain VI (consensus DLKPEN) and domain VIII (consensus G(T/S)XX(Y/F)XAPE) are indicative of serine/threonine specificity (Hanks et al., 1988). The two Ds insertion loci displayed 84% identity at the protein level while in the intron region they showed only 52% nucleotide identity. This was a clear indication that the isolated Ds flanking Solanum tuberosum protein kinase (StPK) represented two distinct Ds tagged loci in mutant 1000, StPK-A and StPK-B. FIG. 6(A) shows the nucleotide sequence of StPK-B (SEQ ID NO: 1) and FIG. 6(B) shows the deduced amino acid sequence of StPK-B (SEQ ID NO: 2).

[0054] Although the protein identity was less than 50%, all characteristic protein kinase domains and conserved amino acids were present in the potato insertion loci StPK-A and StPK-B (except for domain X and XI in StPK-A), including the intron position at exactly the same position in the serine/threonine specific domain VIII. Therefore, it is probable that these serine/threonine protein kinases are similarly functional in the signal transduction pathway leading to P. infestans resistance and perhaps other pathogens.

[0055] Surprisingly, the StPks are more homologous to the protein kinase domain of the rice resistance gene Xa21 than to the earlier identified Solanaceous tomato resistance genes Pto (Martin et al., 1993) and Pti (Zhou et al., 1995). More surprisingly, since a homologue of Pto was mapped to the R1 chromosomal 5 area (Leister et al., 1996). These tomato serine/threonine kinases are functional in the signal transduction pathway leading to a hypersensitive response reaction upon infection with Pseudomonas syringae pv. tomato strains expressing the avirulence gene avrPto (Zhou et al., 1997). In Xa21, other rice homologs (Tarchini et al., 2000) and in the StPK-A and StPK-B the conserved intron position in domain VIII indicates a conserved gene family among monocots and dicots. No intron position was identified in the tomato serine/threonine kinases Pto and Ptil. Among the 11 kinase specific domains only minor differences were observed between the potato kinases and Xa21 on one hand and Pto and Ptil on the other hand (FIG. 5b). But overall amino acid homology determined that the potato sequences were more related to Xa21 than to the tomato kinases Pto and Ptil. Domain IV, with no general consensus, showed a high homology between Xa21 and the potato sequences while Pto and Ptil contained different amino acids in this area. Whether this difference determines a clear difference in function or signaling pathway for these kinases needs to be studied.

Identification of Potato Protein Kinase (StPK) Homologs

[0056] To characterize the structure of the StPK homologs in R1 resistant and susceptible plants several sets of primers were designed and used in PCR analysis. Primers EE1 and EE2 (FIG. 5a) could amplify a product of expected size of about 470 bp and a second product of about 370 bp from the R1 resistant parent J91-6167-2, the susceptible parent 87-1024-2 and several R1 resistant and susceptible progeny (J92-6400-A1, -A2, -A3, -A4, -A5 and -A6). Sequencing the PCR products derived from J91-6167-2, 87-1024-2, J92-6400-A1 and -A4 identified 10 different StPKs (Table 4). In FIG. 7 the DNA sequences of the StPK homologs are shown (partial sequences of the PCR products), SEQ ID NO:3-12. StPK-A was not identified in any of the plants by using this primer combination. From the susceptible parental clone 87-1024-2, StPK-B was isolated. Two additional StPK homologs, StPK-C and -D were identified several times in both R1 resistant and susceptible clones. StPK-D was the 370 bp PCR product and had a deletion of 108 bp making it very likely a non-functional StPK. From the R1 resistant plants two additional StPK homologs, StPK-E and -I were isolated and from the susceptible plants 5 additional homologs were isolated, StPK-F, -G, -H, -J and -K (Table 4). The sequences of StPK-F and StPK-G shown in FIG. 7 are smaller than they actually are due to sequencing problems. The isolation of these many StPK homologs indicated that these serine/threonine protein kinases represent a multigene family in S. tuberosum. This was confirmed by DNA hybridization, since StPK-B identified over 30 hybridizing fragments in HindIII or EcoR1 digested genomic DNA of a single resistant or susceptible potato clone. TABLE 4 Homologs of Solanum tuberosum protein kinases (StPK) isolated from R1 resistant and susceptible clones using primers EE1 and EE2 (FIG. 5a) R1r rr rr progeny progeny % R1r parent J92- J92- StPK identity to parent 1024- 6400- 6400- Total homologue StPK-B 6167-2 2 A4 A1 Clones StPK-B 100 1 1 StPK-C 92 2 3 2 7 StPK-DA 82 5 3 5 13 StPK-E 91 1 1 StPK-F 91 1 1 StPK-G 86 1 1 StPK-H 90 1 1 StPK-I 89 1 1 StPK-J 91 1 1 StPK-K 94 2 2 Total 8 7 9 5 29

[0057] A second set of primers, EE3 and EE6 (FIG. 5a), of which primer EE6 is located downstream of the second exon of StPK-B, was specific enough to identify StPK-B in all analyzed plants. So, this StPK homologue is present in 87-1024-2 (identified with EE1 and EE2), in J91-6167-2 and in several tested R1 resistant and susceptible progeny of population J92-6700, including -A16 from which the tagging population was derived. The StPK-B gene is therefore independent of the R1 locus.

[0058] A third set of primers, EE8 and EE10 (FIG. 5a), was designed on low homologous regions between StPK-A and StPK-B and specifically identified the StPK-A locus after BglII digestion of the PCR products. Analyses of all the parental genotypes used in the different crossings identified that StPK-A is present in the susceptible parent 87-1024-2 that was used to produce the starting population from which J92-6400-A16 was selected (El-Kharbotly et al., 1995).

[0059] Both Ds transposon insertions in mutant 1000 are loci that occur solely or also in plants that do not carry the R1 gene. Therefore, it is very unlikely that StPK-A or StPK-B are the R1 gene itself. The Ds mutagenized StPK loci were designated respectively rpr-1 and rpr-2 (Required for Phytophthora infestans resistance). Both homologs cover a complete (or almost complete) serine/threonine protein kinase ORF with all conserved characteristics including a conserved intron position. The Ds insertions in Rpr1 and Rpr2 probably reduce their expression explaining the incomplete R1 type HR resistance reaction in mutant 1000. Examples of such mutants that can produce a phenotype are given by mutation in one or two genes of a multigene family (Gilliland et al., 1998). The mutations may also be semidominant due to a specific structure as described due to transposon or T-DNA insertions or inversions (Bender and Fink, 1995) (English and Jones, 1998) (Stam et al., 1998).

[0060] If the StPK homologs are similar to the Xa21 gene structure with an LRR additional to the kinase domain, then in StPK-A the Ds insertion in the serine/threonine kinase, 46 bp upstream of the intron, would probably form a truncated LRR protein without a functional kinase domain. This putative truncated LRR domain could possibly compete with the functional LRR-kinase genes, reducing or delaying the signal transduction to exhibit partial P. infestans resistance.

[0061] StPK-B contains a Ds insertion downstream of a serine/threonine protein in kinase. For this insertion Ds 5′ promoter activity (Rudenko et al., 1994) could result in the production of an antisense RNA. Post transciptional gene silencing due to the formed aberrant RNA could result in a reduction of kinase activity making the signaling pathway leading to the R1 type HR response less effective. This might explain the semi-dominant mutation leading to a mutated R1 resistance phenotype in regenerant 1000. A delay in HR response could allow escape of the P. infestans from necrotic regions resulting in sporulation and further colonization of the infected leaves.

Transformation of StPK Gene Constructs Conferring Resistance

[0062] The StPK-B gene fragment was isolated and incorporated in binary vectors for transforming plants. A suitable vector construct with appropriate regulatory sequences including promoter sequences, terminator fragments, polyadenylation sequences, enhancer sequences, marker genes and other appropriate sequences. The StPK-B fragment encodes the kinase domain but lacks the N-terminal part including the translation initiation part. Suitable constructs (I) and (II) are shown in FIG. 8. In one construct (I) a complete kinase encoding gene was made with the StPK-B gene consisting of the DNA fragment shown as Seq ID 1, with a translation start coding for the methionine codon in frame with the open reading frame shown in Seq ID 2. In this construct-I the engineered StPK-B gene was cloned in between the constitutive CaMV 35S promoter and a nopaline synthase (Nos) terminator in the vector pBINPLUS (van Engelen et al., 1995). In another construct type (II) a translational fusion made between the StPK-B fragment of SEQ ID1and a N-terminal part of the complete gene from StPK-B or homologues genes is made. These gene fusions are cloned in between the appropriate regulatory promoter and terminator sequences in pBINPLUS

[0063] The above mentioned recombinant binary vectors are possible to construct by persons skilled in the art including the transfer into appropriate Agrobacterium strains and checking for their stable presence in the Agrobacterium. The recombinant Agrobacterium construct containing the StPK-B overexpression cassette are transformed into potato plants by established procedures (El-Kharbotly et al., 1995). A set of transformants are regenerated and multiplied in vitro by cutting. About 5 regenerated plantlets from each individual transformant are transferred to the greenhouse.

[0064] At about 6 weeks after transferring to the greenhouse the replicated sample of the transformants are tested by the detached leaf test for Phytophthora infestans resistance as described in detail above. From each plant two leaflets are taken, amounting to 10 leaf samples per individual transformant. The resistance score over the replicate samples provides a quantitative estimate of the resistance reaction and allows the selection of plants significantly resistant to infection by Phytophthora.

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[0120] Wolters, A. M. A., Schoenmakers, H. C. H, van der Meulen-Muisers, J. J. M, van der Knaap, E., Derks, F. H. M., Koornneef, M. and Zelcer, A. (1991) Limited DNA elimination from the irradiated potato parent in fusion products of albino Lycopersicon esculentuin and Solanum tuberosum. Theoretical and Applied Genetics 8, 225-232.

[0121] Zhou, J., Loh, Y. -T., Bressan, R. A. and Martin, G. B. (1995) The tomato gene Pti1 encodes a serine/threonine kinase that is phosphorylated by Pto and is involved in the hypersensitive response. Cell Cambridge 83, 925-935.

[0122] Zhou, J. M., Tang, X. Y. and Martin, G. B. (1997) The Pto kinase conferring resistance to tomato bacterial speck disease interacts with proteins that bind a cis-element of pathogenesis-related genes. EMBO Journal 16, 3207-3218.

1 23 1 1309 DNA Solanum tuberosum StPK-B 1 tcaggtgttg gtgctgcaga tcaaaactca tcaattagtt tcttatcacg agattcaaca 60 agcaacaaat aattttgatg ataaatcaaa tttaattggt gagggaagct ctggctctgt 120 gtacaaaggc attttatcta ttggaactgt agtggccata aaggttctgg atttggaaaa 180 tgagcaagta tgcaagaggt ttgataccga atgcaaagtg atgagaaatg ttagacacag 240 aaatcttgtt ccagtgatca ctacatgttc tagtgactat ataagaggct ttgttatgcc 300 aattatgccc aatggaagtc ttgagaattg gctgtacaaa gaagatcgcc acttgaacct 360 tcatcaaaga gtaactgtaa tgcttgatgc agctatggca gttgaatatc tacatcattg 420 tcatgttgct ccaatagttc attgcgacct aaagccagcc aacgttcttt tggatgaaga 480 tatggtggct catgttggtg attttggaat ctctaaaatt ttagctataa gcaagtccat 540 ggcctatacc gagacattgg gtactcttgg atacattgca ccaggtataa aaaatctacc 600 ctctttgatt ttctcttatc ataattaaac ctctctaaat tctaccagta agaaaaagca 660 aggatttatt tatgcagaat tattgttgta tttcaattga gtaacttttc ttcaattctt 720 ttctaagaat atggctcgga gggaatagtg tccgctagtg gtgatgttta tagttatggc 780 attatgttga tggaggtttt gaccaaaaga cggccaacag atgaagatat atgcaatgaa 840 aatcttgacc tgaggaaatg gataacacaa tcattttcag ggagtatgat ggatgttgtg 900 gatgctaatc ttttttctga ggaagaacaa attacttgta aaagtgaaat gtgcatagcc 960 tccatgatag aattggcttt agactgcaca aagaaaatgc cagaatcaag agtaaccatg 1020 aaagaagtag tcaagaggct taacaaaatc aagaacacat ttttggaaat gtagaagtga 1080 tcagcatctc tttctgatct gcaagttaac ttgttgcttt ttgtttactg gtttctttag 1140 taaaggcgta tgtactactc gaagtcatgt attgtttata ctttagagtg ttgcattttg 1200 gagaagaaag gcattgttcc gaggaagtgg taatatatca tctctttata ggttggttgg 1260 tgcaattgat tttttagatt attttctata aatttcgctc acttgttcg 1309 2 297 PRT Solanum tuberosum StPK-B 2 Ile Lys Thr His Gln Leu Val Ser Tyr His Glu Ile Gln Gln Ala Thr 1 5 10 15 Asn Asn Phe Asp Asp Lys Ser Asn Leu Ile Gly Glu Gly Ser Ser Gly 20 25 30 Ser Val Tyr Lys Gly Ile Leu Ser Ile Gly Thr Val Val Ala Ile Lys 35 40 45 Val Leu Asp Leu Glu Asn Glu Gln Val Cys Lys Arg Phe Asp Thr Glu 50 55 60 Cys Lys Val Met Arg Asn Val Arg His Arg Asn Leu Val Pro Val Ile 65 70 75 80 Thr Thr Cys Ser Ser Asp Tyr Ile Arg Gly Phe Val Met Pro Ile Met 85 90 95 Pro Asn Gly Ser Leu Glu Asn Trp Leu Tyr Lys Glu Asp Arg His Leu 100 105 110 Asn Leu His Gln Arg Val Thr Val Met Leu Asp Ala Ala Met Ala Val 115 120 125 Glu Tyr Leu His His Cys His Val Ala Pro Ile Val His Cys Asp Leu 130 135 140 Lys Pro Ala Asn Val Leu Leu Asp Glu Asp Met Val Ala His Val Gly 145 150 155 160 Asp Phe Gly Ile Ser Lys Ile Leu Ala Ile Ser Lys Ser Met Ala Tyr 165 170 175 Thr Glu Thr Leu Gly Thr Leu Gly Tyr Ile Ala Pro Glu Tyr Gly Ser 180 185 190 Glu Gly Ile Val Ser Ala Ser Gly Asp Val Tyr Ser Tyr Gly Ile Met 195 200 205 Leu Met Glu Val Leu Thr Lys Arg Arg Pro Thr Asp Glu Asp Ile Cys 210 215 220 Asn Glu Asn Leu Asp Leu Arg Lys Trp Ile Thr Gln Ser Phe Ser Gly 225 230 235 240 Ser Met Met Asp Val Val Asp Ala Asn Leu Phe Ser Glu Glu Glu Gln 245 250 255 Ile Thr Cys Lys Ser Glu Met Cys Ile Ala Ser Met Ile Glu Leu Ala 260 265 270 Leu Asp Cys Thr Lys Lys Met Pro Glu Ser Arg Val Thr Met Lys Glu 275 280 285 Val Val Lys Arg Leu Asn Lys Ile Lys 290 295 3 820 DNA Solanum tuberosum StPK-A 3 ggtgttggtg ctggagatca aaactaatca attgatttct tatcatgaga ttcaacaagt 60 aacaaataat tttgatggat ccaatttaat tggcgaggga agctctggct ctgtgtacaa 120 aggcacatta tcaagtggaa ctacggtggc cataaaggtt ctggatttgg aaaatgagca 180 agtatgcaag aggtttgrta cagaatgcga agtgatgaga aatgtcagac atagaaatct 240 tgttccagtg attactactt gttctagtga ctatayarca gcctttgtyc tgaaatatat 300 gtcawatggg agtcacgaaa attggttgta cagagaagtt cgccacttga accttcttca 360 aagagtcact gtaatgcttg atgcggctat ggcaattgaa tatctacatc atggcaatga 420 cactgtgata gttcattgca gacataaacc cagccaacgt tcttttggat gaagatatgg 480 tggcgcatgt aggagatttt ggaatctcta agatcttagc cgcaagcaag tccctgacac 540 aaaccgagac attgggcact cttggataca ttgcaccagg tatactaaaa ttataacctt 600 tctatttaat ttttctctta tcaaaatcaa gcccttgaaa attctaggac taaataaaaa 660 gcaagtcttt gttagtatga gcattattgc tatatccaaa tgagttagtt ctttttcatt 720 ttcgttcttt taagagtacg gctcagaagg aatagtgtcg gctagtggtg atgtttacag 780 ttacggcatc atgttgatgg aggttttgac gaaaagaagg 820 4 447 DNA Solanum tuberosum StPK-C 4 acattgggca ctcttggata cattgcacca ggtataaaaa atctactctt tttatcataa 60 taaagcctct ccaaattcta caagtacaaa agcaagcttt tatttatgca gaattattgt 120 tgtatttcaa ttgaattaac ttttttttca atcctttttt aagaatatgg ctcggatgga 180 atagtgtctg ctagtggcga tgtttatagt tacggcatca tgttgatgga ggttttgacg 240 aaaagaaggc caacaaatga agagatatgc aatgaaaatc ttgacttgag gaaatggatc 300 acacaatcat tttcagggag tatgatggac gttgtggatg ccaatctttt ctccgaggaa 360 gaacagatca cttcagaaag tgaaatctgc atagcgtcca tgatagaatt gggtttagac 420 tgcacaaaga aaatgccaga atcaaga 447 5 366 DNA Solanum tuberosum StPK-D 5 aacattgggc actcttggat acattgcacc aggtatactt aaattataac ctatctattt 60 gatttttctc ttatcaaaat caagcccttg aaaattctag gactaaataa aaagcaagtc 120 tttgttatta gtacaagcat tattgttata tccaaatgag ttattctttt tcattttcga 180 tcttttaaga atatggctca gaaggaatag tttccgctag tggtgatgtt tacaaggact 240 gtgatggacg ttgtggattc caaccttttt tgtgaggaag aacaaatcac taggaaaagt 300 gaaatctgca tagcctccat gatagaattg gctttagatt gcacaaagaa aatgccagaa 360 tcaaga 366 6 468 DNA Solanum tuberosum StPK-E 6 acattgggca ctcttggata catggcacca ggtataaaaa agaatctact ctctttgatt 60 ttctcttatc ataattaatt aagcctctcc aagttctaga agtaaaagat gcaagttttt 120 atttattcag aattattgtt gtatttcaat tgaataactg tttttttctc aacccttttc 180 tatgaatatg gctcggaggg aatagtgtcc actagtggtg atgtttatag ttacggcatc 240 atgttgatgg aggttttgac caagagaagg ccaacagatg aagagatatg caatgaaact 300 cttgacttga ggaaatggat cacacaatca ttttcaggga gtatgatgga cgttgtggat 360 gccaatcttt tctccgagga agaacagatc acttcagaaa gtgaaatctg cattgcgtcc 420 atgatagaat tgggtctaga ctgcacaaag aaaatgccag aatcaaga 468 7 360 DNA Solanum tuberosum StPK-F 7 aaaaaagcaa gtcttcattt aggcagaatt attgttgtat ttcaagggag taacttttcc 60 tcaatccttt tctaagaata tggctcagag ggaatagtgt cttctagtgg tgatgtttat 120 agctatggca tcatgttgat ggaagtcttg accgaaagaa ggccaacaga tgaagagata 180 tgcaatgaaa atcttgacct gaggaaatgg ataatacaat cattttcagg gagtatgatg 240 gacgttgtcg atgccaatct tttttacgag gaagaacaaa ccactagtaa aagtgaaatc 300 tgcatagcgt ccatgataga attgggttta gattgcacaa agaaaatgcc agaatcaaga 360 8 360 DNA Solanum tuberosum StPK-G 8 tctccaagtt gtagaagtaa aaagagaact attgttatat ttcaattgag caacttttgg 60 tcaatcattt tctaagaata tggatcagag ggaatagtgt ctgctagtgg tgatgtttat 120 agctacggaa tcatgttgat ggaggttttg accaaaagaa ggccaacaga tgaagagata 180 tgtaatcaaa atcttgacct gaggaaatgg ataatacaat cattttcagg gagtatgacg 240 gacatcgtgg atgccaatat tttttctgag gaagaacaaa ttacttgtaa aagtaaaatg 300 tgcatagcct ccatgataga attggcttta gactgcacaa agaaaatgcc agaatcaaga 360 9 442 DNA Solanum tuberosum StPK-H 9 acattgggca ctcttggata cattgcacca ggtataagaa aatctactct cattgatttt 60 ctcttatcat aattaagcct ctccaattgt tgtagaagta aaaatagaat cattgtattt 120 caattgagta acctttcttc aatccttttc taagaatatg gctcggaggg aatagtgact 180 gtctactagt ggtgatgttt atagctacgg catcatgctg atggaggttt tgacgaaaag 240 aaggccaaca gatgaagaga tatgcaatga aattcttgac ttgaggaaat ggatcacact 300 atcattttca gggagtatgt tggacattgt ggatgccaat attttttgtg aggaagaaca 360 aatcactagt aaaagtgaaa tgtgcatagc ctccatgata gaaccgtctt tagactgcac 420 aaagaaaatg ccagaatcaa ga 442 10 456 DNA Solanum tuberosum StPK-I 10 attgggcact cttggataca tagcaccagg tataaaaaaa tttactctct ttgattttct 60 tttatatcat aattaagcct ctccaaattc tacaagtaga aaaaaacaag ttttcattta 120 tgcagaatta ttgttgtatt tcaattgagt aacttttctt caatcctttt ctaagaatat 180 ggctcaaagg gaatagtgtc tgctagtggt gatgtttata gctatggcat catgttgacc 240 tgaggaaatg gataatacaa tcttgatgaa aagctatgca atgaaaatct tgacctgagg 300 aaatggataa tacaatcatt tttagggagt atgatggaca ttgtggatgc caatcttttt 360 tgtgaggaag tacaaatcac ttgtaaaagt gaaatgtgcc tagcctccat gatagaattg 420 gctttagatt gcacaaagaa aatgccagaa tcaaga 456 11 458 DNA Solanum tuberosum StPK-J 11 acattgggca ctcttggata cattgcacca aggtataaaa aatctactca ctttgatttt 60 cttttatcat aataaagcct ctccaaattc tacaagtata aaagcaacct tttatttatg 120 cagaattatt gttgtatttc aattgaatta actttttttt caatcctttt ttaagaatat 180 ggctcggatg gaatagtatc tgctagttgc gatgtttata gttacggcat catgttgatg 240 gaggttttga cgaaaagaag gccaacagat gaagagatat gcaatgaaaa tcttgacctg 300 aggaaatgga taatacaatc attttcaggg agtatgatgg acgttgtcga tgccaatctt 360 tttacgagga agaacaaatc actagtaaaa gtgaaatctg catagcgtcc atgatagaat 420 tgggtttaga ttgcacaaag aaaatgccag aatcaaga 458 12 468 DNA Solanum tuberosum StPK-K 12 acattgggca ctcttggata cattgcacca ggtataaaaa aatctactct ctttgatttt 60 ctcttatatc ataattaagc ctctctaagg tctaaaagtt aaaaaaaaaa aaaaacaagt 120 tttcatttat gcagaattat tgttgaattt caattgagta acttttcttc aatccttctc 180 taagaatatg gctcggaggg aatagtgtct gctagtggtg atgtttatag ctacggcatc 240 atgttgatgg aggttttgac gaaaagaagg ccaacagatg aagagatatg caatgaaaat 300 cttgacttga ggaaatggat cacacaatca ttttcaggga gtatgatgga tgttgtggat 360 gccaatctat tttctgcgga agaacaaatc actagtaaaa gtgaaatgtg catagcctcc 420 atgatagaat tggctttaga ctgcacaaag aaaatgccag aatcaaga 468 13 216 PRT Solanum tuberosum StPK-A 13 Ile Lys Thr Asn Gln Leu Ile Ser Tyr His Glu Ile Gln Gln Val Thr 1 5 10 15 Asn Asn Phe Asp Gly Ser Asn Leu Ile Gly Glu Gly Ser Ser Gly Ser 20 25 30 Val Tyr Lys Gly Thr Leu Ser Ser Gly Thr Thr Val Ala Ile Lys Val 35 40 45 Leu Asp Leu Glu Asn Glu Gln Val Cys Lys Arg Phe Xaa Thr Glu Cys 50 55 60 Glu Val Met Arg Asn Val Arg His Arg Asn Leu Val Pro Val Ile Thr 65 70 75 80 Thr Cys Ser Ser Asp Tyr Xaa Xaa Ala Phe Val Leu Lys Tyr Met Ser 85 90 95 Xaa Gly Ser His Glu Asn Trp Leu Tyr Arg Glu Val Arg His Leu Asn 100 105 110 Leu Leu Gln Arg Val Thr Val Met Leu Asp Ala Ala Met Ala Ile Glu 115 120 125 Tyr Leu His His Gly Asn Asp Thr Val Ile Val His Cys Asp Ile Asn 130 135 140 Pro Ala Asn Val Leu Leu Asp Glu Asp Met Val Ala His Val Gly Asp 145 150 155 160 Phe Gly Ile Ser Lys Ile Leu Ala Ala Ser Lys Ser Leu Thr Gln Thr 165 170 175 Glu Thr Leu Gly Thr Leu Gly Tyr Ile Ala Pro Glu Tyr Gly Ser Glu 180 185 190 Gly Ile Val Ser Ala Ser Gly Asp Val Tyr Ser Tyr Gly Ile Met Leu 195 200 205 Met Glu Val Leu Thr Lys Arg Arg 210 215 14 20 DNA Artificial Sequence Description of Artificial Sequence primer 14 gcgcgttcaa aagtcgccta 20 15 20 DNA Artificial Sequence Description of Artificial Sequence primer 15 gtcaagcact tccggaatcg 20 16 22 DNA Artificial Sequence Description of Artificial Sequence primer 16 acattgggca ctcttggata ca 22 17 23 DNA Artificial Sequence Description of Artificial Sequence primer 17 tcttgattct ggcattttct ttg 23 18 21 DNA Artificial Sequence Description of Artificial Sequence primer 18 cctgacacaa accgagacat t 21 19 18 DNA Artificial Sequence Description of Artificial Sequence primer 19 aacaatgcct ttcttctc 18 20 23 DNA Artificial Sequence Description of Artificial Sequence primer 20 gcacattatc aagtggaact acg 23 21 24 DNA Artificial Sequence Description of Artificial Sequence primer 21 ctgagccgta ctcttaaaag aacg 24 22 20 DNA Artificial Sequence Description of Artificial Sequence primer 22 cgggatgatc ccgtttcgtt 20 23 20 DNA Artificial Sequence Description of Artificial Sequence primer 23 gataacggtc ggtacgggat 20 

1. An isolated DNA sequence which encodes a protein having the amino acid sequence given in SEQ ID NO: 2 or a functionally homologous protein having an amino acid sequence showing an indentity of at least 80% to SEQ ED NO: 2, which protein confers Phytophthora infestans resistance on plants.
 2. The DNA sequence according to claim 1, characterized in that the functionally homologous protein has an amino acid sequence showing an identity of at least 85% to SEQ ID NO:
 2. 3. The DNA sequence according to claim 1 or 2, characterized in that it comprises the nucleotide sequence selected from the group consisting of: a) the DNA sequence given in SEQ ID NO: 1 and its complementary strand, and b) DNA sequences hybridizing to the sequences in (a) under stringent hybridization conditions.
 4. The DNA sequence according to claim 3, characterized in that it comprises the nucleotide sequence of nucleotides 20 to 1053 of SEQ ID NO:
 1. 5. The DNA sequence according to claim 3, characterized in that it comprises the nucleotide sequence of nucleotides 20 to 583 and 727 to 1053 of SEQ ID NO:
 1. 6. A protein encoded by the DNA sequence of any of claims 1 to
 5. 7. A recombinant vector comprising a DNA sequence under control of an appropriate promoter and regulatory elements for expression in a host cell, wherein the DNA sequence is as defined in any of claims 1 to
 5. 8. Use of a DNA sequence of any of claims 1 to 5 or a recombinant vector of claim 7 for the production of a transgenic plant.
 9. A host cell comprising a DNA sequence of any of claims 1 to 5 or a recombinant vector of claim
 7. 10. A host cell according to claim 9 which is a plant cell.
 11. A plant or any part thereof comprising a plant cell according to claim
 10. 12. Seed, selfed or hybrid progeny or descendant of a plant according to claim 11, or any part thereof.
 13. A method of conferring Phytophthora infestans resistance on a plant, comprising the steps of i) introducing a DNA sequence of any of claims 1 to 5 or a recombinant vector of claim 7 into a cell of the plant or an ancestor thereof, ii) regenerating plants from the obtained transgenic cells, and iii) selecting plants exhibiting Phytophthora infestans resistance. 